Oxygen activation and the conservation of energy in cell respiration

The CuAsite of the caa3-type oxidase of Bacillus subtilis is a mixed-valence binuclear copper centre

A copper-containing domain of the caa3-type oxidase from Bacillus subtilis has been expressed as a water-soluble protein in the cytoplasm of Escherichia coli. Electron paramagnetic resonance (EPR) spectra of this purple domain show well-resolved lines in the gz resonance, both at X-band and S-band frequencies. Interpretation of EPR spectra and analytical data indicate a binuclear copper site consisting of one Cu2+ and one Cu1+. This copper site closely resembles CuA in subunit II of cytochrome c oxidase and is shown here to be a mixed-valence [Cu2+-Cu1+] binuclear centre.

Inhibition of the synthesis of a cytochrome-c-oxidase subunit isoform by antisense RNA

To investigate the role of subunit VIIe, an oxygen-regulated subunit isoform of Dictyostelium discoideum cytochrome-c oxidase, the full-length cDNA was inserted into an expression vector under the control of an actin promoter in the sense and antisense orientation. The DNA constructs were used for stable transformation of the slime mold amoebae. In most of the 28 antisense clones tested, the concentration of cytochrome-c oxidase was lowered compared to the wild type, while no significant changes were found in the sense mutants. Antisense RNA was abundantly expressed, leading to a drastic reduction of the steady-state level of the endogenous subunit VIIe mRNA, which was decreased up to 20-30% the level observed in parent cells. In these transformants, the amount of the target polypeptide and cytochrome c oxidase was 40-50% and 60-70% of control, respectively. A similar decrease was found in the level of the remaining nuclear and mitochondrial subunits. Unexpectedly, these changes affected neither basal nor uncoupled cell respiration suggesting an increase of the enzyme specific activity. Hypoxia completely relieved the cytochrome-c-oxidase deficit. These results indicate that subunit VII is needed for an efficient assembly of the protein complex and provide evidence for its involvement in the modulation of the enzyme activity.

The gene encoding cytochrome-c oxidase subunit I from Synechocystis PCC6803

The gene (coxI or CoxA) encoding subunit I (COI) of cytochrome-c oxidase (cytochrome aa3) of Synechocystis PCC6803, Synechococcus PCC7942 (Anacystis nidulans R2) and Nostoc PCC8002 (Nostoc Mac), was identified by heterologous hybridization of chromosomal digests with a 17-bp oligodeoxyribonucleotide (probe C) derived from the coxI of Paracoccus denitrificans. A single genomic fragment was found to bind to probe C in all chromosomal digests. Due to its favorable signal-to-noise ratio, the genome of Synechocystis was chosen for the isolation and sequencing of this gene. A genomic DNA library in pUC18 was screened with probe C. The two probe C-positive plasmids, pDAUV1 and pDAUV2, contained a 1-kb overlapping region, with the conserved 17-bp sequence encoding the CuB-binding region of the COI polypeptide. These plasmids were subcloned into competent Escherichia coli DH5 alpha cells, and the nucleotide sequences were determined. The deduced amino acid (aa) sequences of Synechocystis COI and homologous proteins from a variety of prokaryotic and eukaryotic organisms showed an overall similarity of between 38.6 and 45.8%. Hydropathy plots revealed 12 potential transmembrane helices. All of the six histidines needed for the binding of heme a and the heme a3/CuB bimetallic center are present in the expected positions of the Synechocystis COI protein (533 aa, M(r) 59,390). A monospecific antibody raised against P. denitrificans COI gave an unequivocal immunological cross-reaction on Western blots of membrane preparations from Synechocystis, Anacystis and Nostoc, showing that the product of gene coxI is indeed synthesized and incorporated into cyanobacterial membranes.

Intracellular expression of Vitreoscilla hemoglobin alters Escherichia coli energy metabolism under oxygen-limited conditions

An earlier stoichiometric analysis of oxygen-limited metabolism of Escherichia coli expressing cloned Vitreoscilla hemoglobin (VHb) suggested improved efficiency of ATP production relative to wild-type controls [Khosla, C., Curtis, J. E., DeModena, J., Rinas, J. & Bailey, J. E. (1990) BioTechnol. 8, 849-853]. This hypothesis has been further examined by determining several energetic parameters of different VHb-expressing E. coli (VHb+) strains relative to controls not expressing VHb (VHb-). The H+/O ratio, the transmembrane delta pH, and the ATP content of VHb+ constructs are 1.5, 1.6 and 2 times, respectively, corresponding values in VHb- controls. VHb was expressed using a low-copy-number vector in E. coli mutant strains lacking cytochrome o, cytochrome d, or both terminal oxidases; significant growth enhancement due to VHb expression was observed only in the strain having functional cytochrome o and lacking cytochrome d. All of these data obtained using different E. coli strains are consistent with a model of VHb action that hypothesizes enhancement by VHb of activity of the lower oxygen-affinity, higher proton-pumping-efficiency cytochrome o terminal oxidase under oxygen-limited growth conditions.

Structure and evolution of cytochrome oxidase

The structural features of cytochrome oxidases are reviewed in light of their evolution. The substrate specificity (quinol vs. cytochrome c) is reflected in the presence of a unique copper centre (CuA) in cytochrome c oxidases. In several lines of evolution, quinol oxidases have independently lost this copper. Also, the most primitive cytochrome c oxidases do not contain this copper, and electron entry takes place via c-type haems. These enzymes, exemplified by the rhizobial FixN complex, probably remind the first oxidases. They are related to the denitrification enzyme nitric oxide reductase.

Flash-induced membrane potential generation by cytochrome c oxidase

Flash-induced single-electron reduction of cytochrome c oxidase. Compound F (oxoferryl state) by RuII(2,2'-bipyridyl)3(2+) [Nilsson (1992) Proc. Natl. Acad. Sci. USA 89, 6497-6501] gives rise to three phases of membrane potential generation in proteoliposomes with tau values and contributions of ca. 45 microsecond (20%), 1 ms (20%) and 5 ms (60%). The rapid phase is not sensitive to the binuclear centre ligands, such as cyanide or peroxide, and is assigned to vectorial electron transfer from CuA to heme a. The two slow phases kinetically match reoxidation of heme a, require added H2O2 or methyl peroxide for full development, and are completely inhibited by cyanide; evidently, they are associated with the reduction of Compound F to the Ox state by heme a. The charge transfer steps associated with the F to Ox conversion are likely to comprise (i) electrogenic uptake of a 'chemical' proton from the N phase required for protonation of the reduced oxygen atom and (ii) electrogenic H+ pumping across the membrane linked to the F to Ox transition. Assuming heme a 'electrical location' in the middle of the dielectric barrier, the ratio of the rapid to slow electrogenic phase amplitudes indicates that the F to Ox transition is linked to transmembrane translocation of 1.5 charges (protons) in addition to an electrogenic uptake of one 'chemical' proton required to form Fe(3+)-OH- from Fe4+ = O2-. The shortfall in the number of pumped protons and the biphasic kinetics of the millisecond part of the electric response matching biphasic reoxidation of heme a may indicate the presence of 2 forms of Compound F, reduction of only one of which being linked to full proton pumping.

Time-resolved study of tryptophan fluorescence in vesicle reconstituted cytochrome oxidase. Effect of redox transition

Time-resolved study of fluorescence decay of the tryptophan residue in bovine cytochrome c oxidase in phospholipid vesicles is reported for the first time. The effect of the redox state of the protein on its conformation has been investigated using time-resolved decay of tryptophan fluorescence in the oxidised and reduced protein. The fluorescence decay was best fitted using a discrete three exponential model. Amplitude distribution of lifetimes also showed three distinct regions in the analysis of decay profiles by the maximum entropy method (MEM). Results of the time resolved studies showed that the amplitudes as well as the lifetimes of the tryptophan fluorescence remain the same for the oxidised and the reduced states of cytochrome c oxidase, indicating that the environment around tryptophan residues remains more or less unaltered on reduction of the protein. The results suggest that there is no global conformational change in the protein on electron transfer and support the possibility of the existence of local fluctuations in the protein during the redox cycle.

ENDOR and ESEEM studies of cytochrome c oxidase: evidence for exchangeable protons at the CuA site

Electron nuclear double resonance (ENDOR) and electron spin echo envelope modulation (ESEEM) spectroscopies were used to study whether protons in the immediate protein environment around CuA in cytochrome c oxidase are susceptible to solvent exchange. The enzyme was incubated in buffered D2O under resting or turnover conditions for 90 min and then frozen to quench the hydrogen/deuterium-exchange process. ENDOR spectra of the deuterated sample were essentially identical to those of control samples. The ESEEM spectra, however, provided a clear indication of the introduction of deuterium into the CuA environment following incubation in buffered D2O. The extent of deuterium incorporation was not affected by enzyme turnover. An analysis of the ESEEM data indicated that water is in reasonably close proximity to the CuA site, but not in the immediate coordination sphere of the metal(s). We estimate a minimum distance of 5.4 A between the CuA center and the protein/water interface. This relatively short surface separation distance is consistent with the role of CuA as the immediate oxidant of cytochrome c in the cytochrome oxidase (Hill, B. C. (1991) J. Biol. Chem. 266, 2219-2226).

Fluorescence quenching of reconstituted NCD-4-labeled cytochrome c oxidase complex by DOXYL-stearic acids

It has been known for some time that dicyclohexylcarbodiimide (DCCD) inhibits the proton translocation function of the cytochrome c oxidase complex (CcO) and that there is one major site in subunit III which is modified upon reaction with DCCD (Glu-90 for the bovine enzyme). We have examined the reaction of bovine CcO with N-cyclohexyl-N'-(4-dimethylamino-alpha-napthyl)carbodiimide (NCD-4), a fluorescent analog of DCCD. NCD-4 labeling of CcO is strongly inhibited by DCCD implicating Glu-90 of subunit III as the site of chemical modification by NCD-4. The fluorescence of reconstituted NCD-4-labeled bovine CcO is strongly quenched by hydrophobic nitroxides, whereas hydrophilic nitroxides and iodide ions have a reduced quenching ability. It is concluded that the Glu-90 of subunit III resides near the protein-lipid interface of the membrane spanning region of the enzyme. Different quenching abilities of 5-, 7-, 10-, 12-, and 16-4,4-dimethyl-3-oxazolinyloxy-stearic acids suggest that the NCD-4 label is located in the membrane bilayer in the region near the middle of the hydrocarbon tail of stearic acid. In light of these results, it is unlikely that Glu-90 is part of a proton channel that is associated with the proton pumping machinery of the enzyme but the outcome of this study does not eliminate an allosteric regulatory role for this residue.

Metalloenzymes, structural motifs, and inorganic models

Metalloenzymes effect a variety of important chemical transformations, often involving small molecule substrates or products such as molecular oxygen, hydrogen, nitrogen, and water. A diverse array of ions or metal clusters is observed at the active-site cores, but living systems use basic recurring structures that have been modified or tuned for specific purposes. Inorganic chemists are actively involved in the elucidation of the structure, spectroscopy, and mechanism of action of these biological catalysts, in part through a synthetic modeling approach involving biomimetic studies.

Genetic fusion of subunits I, II, and III of the cytochrome bo ubiquinol oxidase from Escherichia coli results in a fully assembled and active enzyme

The cytochrome bo ubiquinol oxidase from Escherichia coli is a five-subunit enzyme which is a member of the superfamily of heme-copper respiratory oxidases. Three of the subunits (I, II, and III) are homologous to the three mitochondrial encoded subunits of the eukaryotic aa3-type cytochrome c oxidase. Subunits, I, II, and III of the eukaryotic oxidase contain 12, 2, and 7 putative transmembrane spans, respectively. The hydropathy profiles of the subunits of most other members of this oxidase superfamily are consistent with these structures. However, subunit I from the E. coli oxidase contains 15 transmembrane spans, with one additional span at the N-terminus and two additional spans at the C-terminus in comparison to the eukaryotic oxidase. The additional transmembrane helix at the N-terminus predicts that the amino terminal residue should be on the periplasmic side of the membrane. By deleting the intergenic region between the cyoA and cyoB genes, an in-frame fusion between subunit II (cyoA) and subunit I (cyoB) was generated. This links the C-terminus of subunit II, known to be on the periplasmic side of the membrane, to the N-terminus of subunit I. The resulting oxidase is fully active, and supports the toplogical folding pattern previously suggested for subunit I with the N-terminus in the periplasm. Whereas subunit I of the E. coli oxidase has two additional membrane-spanning helices at the C-terminus, subunit III has two fewer helices than does the corresponding subunit III of the eukaryotic oxidase.(ABSTRACT TRUNCATED AT 250 WORDS)

Kinetics, control, and mechanism of ubiquinone reduction by the mammalian respiratory chain-linked NADH-ubiquinone reductase

In mammalian cells the membrane-bound NADH-quinone oxidoreductase serves as the entry point for oxidation of NADH in the respiratory chain and as the proton-translocating unit which conserves the free energy of the enzyme intramolecular redox reactions as the free energy of the electrochemical proton gradient across the coupling membrane. This review summarizes the kinetic properties of the mammalian enzyme. Emphasis is placed on the hysteretic properties of the enzyme as related to the possible control of intramitochondrial NADH oxidation and to the mechanism of the enzyme interaction with ubiquinone. Recent evidence for participation of flavin and the protein-bound ubisemiquinone pair in the enzyme-catalyzed proton translocation mechanism are discussed.

The steady state behaviour of cytochrome c oxidase in proteoliposomes

Electron transfer to oxygen catalysed by cytochrome c oxidase is accompanied by spectral changes at the binuclear a3CuB centre, both in the soluble enzyme and in membranous systems, indicating spin or ligand state transitions of an iron that remains ferric. The other haem group, cytochrome a, does not change its spectral characteristics significantly during the steady state, but remains partially reduced until anaerobiosis. Cytochrome a3, is fully oxidized in each of its major steady state forms, and reduced upon anaerobiosis to a single ferrous species. Although cytochrome a is normally the immediate electron donor to the binuclear centre, its redox state does not alter under conditions in which the flux through the enzyme is changing significantly. A second electron transfer pathway to the binuclear centre may therefore exist, possibly one in which direct reduction of the binuclear a3CuB centre by CuA occurs. Both cytochrome a and CuA behave as simple electron transfer centres. The energy-conserving chemistry takes place at the binuclear centre in concert with the four-electron reduction of molecular oxygen.

Comparison of ubiquinol and cytochrome c terminal oxidases. An alternative view

There have been numerous instances in the recent literature where the properties of ubiquinol and cytochrome c terminal oxidases are compared. Here we specifically examine the cytochrome bo3-type ubiquinol oxidase from Escherichia coli and the cytochrome aa3-type cytochrome c oxidases. A second redox-active copper site (CuA) is present only in the cytochrome c oxidases and the physiological electron donors for the two enzymes are different (ubiquinol-8 vs. ferrocytochrome c). In our opinion, these differences are significant and most likely indicate that distinct turnover mechanisms are operative in the two enzymes.

Proton pumping by cytochrome oxidase as studied by time-resolved stopped-flow spectrophotometry

The H+/e- stoichiometry for the proton pump of cytochrome c oxidase reportedly varies between 0 and 1, depending on experimental conditions. In this paper, we report the results obtained by a combination of transient optical spectroscopy with a time resolution of 10 ms and a singular value decomposition analysis to follow the kinetics, separate the observed spectral components, and quantitate the stoichiometry of the pump. By using cytochrome oxidase reconstituted into small unilamellar vesicles, we show that the time courses of ferrocytochrome c oxidation and phenol red acidification or alkalinization fit a simple kinetic scheme. The fitting procedure leads to unbiased and objective determination of the H+/e- ratio under various experimental conditions. The proton-pumping stoichiometry was found to be 1.01 +/- 0.10, independent of the number of turnovers, proton back-leak rate, or type of experiment (oxidant or reductant pulse).

Structure of the heme-copper binuclear center of the cytochrome bo complex of Escherichia coli: EPR and Fourier transform infrared spectroscopic studies

The cytochrome bo complex is a terminal quinol oxidase in the aerobic respiratory chain of Escherichia coli and functions as a redox-coupled proton pump. To clarify the structural differences of the binuclear reaction center between the cytochrome bo complex and the mitochondrial cytochrome c oxidase, a combined study using EPR and Fourier transform infrared spectroscopies was carried out. The EPR spectrum of the highly purified cytochrome bo complex in the air-oxidized state showed a broad EPR signal (peak g* = 3.7) from an integer spin system. This confirms the existence of the spin-spin exchange-coupled binuclear site, in which the Feo3+ and CuB2+ centers were bridged by an unknown ligand (X). Binding of azide at the binuclear site as an ionic modulator weakened the strength of the spin-spin exchange coupling and thus caused a narrowing of the broad EPR signal. Binding of another modulator, formate, at the binuclear site caused the formation of EPR signals at g' = 12 and 2.7, which are very similar to those observed for cytochrome c oxidase. Cyanide replaced the bridging ligand (X) to form an Feo(3+)-C-N-CuB2+ structure in which strong spin-spin exchange coupling is expected, leading to a complete EPR-invisible state. Infrared evidence (a 2146 cm-1 C-N stretching band for the cyanide complex and a 2041 cm-1 azide antisymmetric stretching band for the azide complex) supported the theory that these ligands form bridging structures at the binuclear center, as previously observed for cytochrome c oxidase.(ABSTRACT TRUNCATED AT 250 WORDS)

Spectroscopic evidence for a heme-heme binuclear center in the cytochrome bd ubiquinol oxidase from Escherichia coli

The cytochrome bd complex is a ubiquinol oxidase, which is part of the aerobic respiratory chain of Escherichia coli. This enzyme is structurally unrelated to the heme-Cu oxidases such as cytochrome c oxidase. While the cytochrome bd complex contains no copper, it does have three heme prosthetic groups: heme b558, heme b595, and heme d (a chlorin). Heme b558 appears to be involved in the oxidation of quinol, and heme d is known to be the site where oxygen binds and is reduced to water. The role of heme b595, which is high spin, is not known. In this paper, CO is used to probe the oxygen-binding site by use of Fourier transform infrared spectroscopy to monitor the stretching frequency of CO bound to the enzyme. Photodissociation at low temperature (e.g., 20 K) of the CO-heme d adduct results in CO associated with the protein within the heme binding pocket. This photodissociated CO can subsequently relax to form a kinetically trapped CO-heme b595 adduct. The data clearly show that heme d and heme b595 must reside within a common binding pocket in the enzyme. The catalytic active site where oxygen is reduced to water is, thus, properly considered to be a heme d-heme b595 binuclear center. This is analogous to the heme alpha 3-Cu(B) binuclear center in the heme-Cu oxidases. Heme b595 may play roles analogous to those proposed for the Cu(B) component of cytochrome c oxidase.

X-ray absorption spectroscopy of oriented cytochrome oxidase

The polarized X-ray absorption spectra of the copper, iron and zinc sites of mitochondrial cytochrome oxidase in oriented membrane multilayers have been examined. The copper X-ray absorption edge spectra indicate the presence of a tetragonal copper, which we assign as CuB, oriented with the long axis approximately orthogonal to the membrane normal. We have also detected the presence of a relatively long (2.6 A) Cu-S or Cu-Cl interaction, which we assign to a copper-thioether (probably Met210) coordination at the CuA site, with the bond oriented along the membrane normal. The coordination of the zinc, the iron and the CuB heme a3 binuclear site are discussed.

The sequence of electron carriers in the reaction of cytochrome c oxidase with oxygen

Kinetic studies of the electron transfer processes performed by cytochrome oxidase have assigned rates of electron transfer between the metal centers involved in the oxidation of ferrocytochrome c by molecular oxygen. Transient-state studies of the reaction with oxygen have led to the proposal of a sequence of carriers from cytochrome c, to CuA, to cytochrome a, and then to the binuclear (i.e., cytochrome a3-CuB) center. Electron exchange rates between these centers agree with relative center-to-center distances as follows; cytochrome c to CuA 5-7 A, cytochrome c to cytochrome a 20-25 A, CuA to cytochrome a 14-16 A and cytochrome a to cytochrome a3-CuB 8-10 A. It is proposed that the step from cytochrome a to the binuclear center is the key control point in the reaction and that this step is one of the major points of energy transduction in the reaction cycle.

Coordination dynamics of heme-copper oxidases. The ligand shuttle and the control and coupling of electron transfer and proton translocation

Results are presented which, taken with evidence developed by others, suggest a general mechanism for the entry and binding of exogenous ligands (including O2) at the "binuclear site" (CuBFea3) of the heme-copper oxidases. The mechanism includes a "ligand shuttle" wherein the obligatory way station for incoming ligands is CuB and the binding of exogenous ligands at this site triggers the exchange and displacement of endogenous ligands at Fea3. It is suggested that these ligand shuttle reactions might be functionally important in providing a coupling mechanism for electron transfer and proton translocation. Scenarios as to how this might happen are delineated.

Probing heart cytochrome c oxidase structure and function by infrared spectroscopy

IR spectra directly probe specific vibrators in bovine heart cytochrome c oxidase, yielding quantitative as well as qualitative information on structures and reactions at these vibrators. C-O IR spectra reveal that CO binds to Fe2+ a3 as two conformers each in isolated immobile environments sensitive to Fea and/or CuA oxidation state but remarkably insensitive to pH, medium, anesthetics, and other factors that affect activity. C-N IR spectra reveal that the one CN- that binds to fully and partially oxidized enzyme can be in three different structures. These structures vary in relative amounts with redox level, thereby reflecting dynamic electron exchange among Fea, CuA, and CuB with associated changes in protein conformation of likely significance in O2 reduction and H(+)-pumping. Azide IR spectra also reflect redox-dependent long-range effects. The amide I IR bands, due to C-O vibrators of peptide linkages and composed of multiple bands derived from different secondary structures, reveal high levels of alpha-helix (approximately 60%) and subtle changes with redox level and exposure to anesthetics. N2O IR spectra reveal that these anesthetic molecules at clinically relevant levels occupy three sites of different polarity within the enzyme as the enzyme is reversibly, but only partially, inhibited.

Discrete steps in dioxygen activation--the cytochrome oxidase/O2 reaction

The kinetic constraints that are imposed on cytochrome oxidase in its dual function as the terminal oxidant in the respiratory process and as a redox-linked proton pump provide a unique opportunity to investigate the molecular details of biological O2 activation. By using flow/flash techniques, it is possible to visualize individual steps in the O2-binding and reduction process, and results from a number of spectroscopic investigations on the oxidation of reduced cytochrome oxidase by O2 are now available. In this article, we use these results to synthesize a reaction mechanism for O2 activation in the enzyme and to simulate time-concentration profiles for a number of intermediates that have been observed experimentally. Kinetic manifestation of the consequences of coupling exergonic electron transfer to endergonic proton translocation emerge from this analysis. Energetic efficiency in this process apparently requires that potentially toxic intermediate oxidation states of dioxygen accumulate to substantial concentration during the reduction reaction.

Protons, pumps, and potentials: control of cytochrome oxidase

Cytochrome c oxidase oxidizes cytochrome c and reduces molecular oxygen to water. When the enzyme is embedded across a membrane, this process generates electrical and pH gradients, and these gradients inhibit enzyme turnover. This respiratory control process is seen both in intact mitochondria and in reconstituted proteoliposomes. Generation of pH gradients and their role in respiratory control are described. Both electron and proton movement seem to be implicated. A topochemical arrangement of redox centers, like that in the photosynthetic reaction center and the cytochrome bc1 complex, ensures charge separation as a result of electron movement. Proton translocation does not require such a topology, although it does require alternating access to the two sides of the membrane by proton-donating and accepting groups. The sites of respiratory control within the enzyme are discussed and a model presented for electron transfer and proton pumping by the oxidase in the light of current knowledge of the transmembranous location of the redox centers involved.

Insight into the active-site structure and function of cytochrome oxidase by analysis of site-directed mutants of bacterial cytochrome aa3 and cytochrome bo

Cytochrome aa3 of Rhodobacter sphaeroides and cytochrome bo of E. coli are useful models of the more complex cytochrome c oxidase of eukaryotes, as demonstrated by the genetic, spectroscopic, and functional studies reviewed here. A summary of site-directed mutants of conserved residues in these two enzymes is presented and discussed in terms of a current model of the structure of the metal centers and evidence for regions of the protein likely to be involved in proton transfer. The model of ligation of the heme a3 (or o)-CuB center, in which both hemes are bound to helix X of subunit I, has important implications for the pathways and control of electron transfer.

Proton translocation in cytochrome c oxidase: redox linkage through proximal ligand exchange on cytochrome a3

An analysis of resonance Raman scattering data from CO-bound cytochrome c oxidase and from the photodissociated enzyme indicates that histidine may not be coordinated to the iron atom of cytochrome a3 in the CO-bound form of the enzyme. Instead, the data suggest that either a water molecule or a different amino acid residue occupies the proximal ligand position. From these data, it is postulated that ligand exchange on cytochrome a3 can occur under physiological conditions. Studies of mutant hemoglobins have demonstrated that tyrosinate binds preferentially to histidine in the ferric forms of the proteins. In cytochrome c oxidase tyrosine residues are located near the histidine residues recently implicated in coordination to cytochrome a3 (Shapleigh et al., 1992; Hosler et al., this volume). Expanding on these concepts, we propose a model for proton translocation at the O2-binding site based on proximal ligand exchange between tyrosine and histidine on cytochrome a3. The pumping steps take place at the level of the peroxy intermediate and at the level of the ferryl intermediate in the catalytic cycle and are thereby consistent with the recent results of Wilkstrom (1989) who found that proton pumping occurs only at these two steps. It is shown that the model may be readily extended to account for the pumping of two protons at each of the steps.

Resolution of the reaction sequence during the reduction of O2 by cytochrome oxidase

Time-resolved resonance Raman spectroscopy has been used to study the reduction of dioxygen by the mitochondrial enzyme, cytochrome oxidase. In agreement with earlier reports, Fe(2+)-O2 and Fe(3+)-OH- are detected in the initial and final stages of the reaction, respectively. Two additional intermediates, a peroxy [Fe(3+)-O(-)-O-(H)] and a ferryl (Fe4+ = O), occur transiently. The peroxy species shows an oxygen-isotope-sensitive mode at 358 cm-1 that is assigned as the nu(Fe(3+)-O-) stretching vibration. Our kinetic analysis indicates that the peroxy species we detect occurs upon proton uptake from bulk solution; whether this species bridges to Cu(B) remains uncertain. For the ferryl, nu(Fe(4+) = O) is at 790 cm-1. In our time-resolved spectra, the 358 cm-1 mode appears prior to the 790 cm-1 vibration. By using kinetic parameters deduced from the time-resolved Raman work and from a variety of time-resolved optical studies from other laboratories, we have assigned rate constants to several steps in the linear reaction sequence proposed by G. T. Babcock and M. Wikström [(1992) Nature (London) 356, 301-309]. Simulations of this kinetic scheme provide insight into the temporal behavior of key intermediates in the O2 reduction process. A striking aspect of the reaction time course is that rapid O2-binding and trapping chemistry is followed by a progressive slowing down of succeeding steps in the process, which allows the various transient species to build up to concentrations sufficient for their detection by our time-resolved techniques. Our analysis indicates that this behavior reflects a mechanism in which conditions that allow efficient dioxygen bond cleavage are not inherent to the active site but are only established as the reaction proceeds. This catalytic strategy provides an effective means by which to couple the free energy available in late intermediates in the reduction reaction to the proton-pumping function of the enzyme.

Molecular biology of Bacillus subtilis cytochromes

Bacillus subtilis cells must have cytochromes for growth and can synthesize cytochromes of a-, b-, c-, d-, and o-types. After a long lag, our knowledge of the structure, genetics and specific role for these cytochromes is now growing exponentially as the result of recent research. This progress is reviewed here and includes, for example, the discovery of two different cytochrome a systems and genes required for their biogenesis.

The oxygen reactive species of cytochrome-c-oxidase: an alternative view

In a recent review article Babcok and Wikström (Nature, 1992, 356, 301-309) proposed that the species of cytochrome-c-oxidase which binds molecular oxygen during turnover is the so-called mixed valence enzyme, in which the binuclear center cytochrome a3-CuB is reduced, while the cytochrome a/CuA sites are oxidized. This proposal is based on earlier work (Morgan and Wikström, Biochemistry 1991, 30, 948-958) in which it was found that the steady-state reduction levels of cytochrome c and cytochrome a in respiring rat liver mitochondria (sustained by ascorbate and TMPD) are quite different, the latter being much more oxidized than the former; evaluation of the steady-state reduction levels demanded a large correction due to the optical contribution of oxidized TMPD+ which overlaps with the cytochromes. We report below that application of transient spectroscopy and SVD analysis to respiring rat heart myocytes, under conditions in which the contribution of TMPD+ is very small or absent, allows to show that the steady-state reduction levels of cytochrome c and cytochrome a are comparable at all times accessible to measurement in the rapid-scanning stopped-flow spectrophotometer. Our conclusion, in agreement with previous results, is that mixed valence cytochrome-c-oxidase as defined above is not the prevailing oxygen binding species of cytochrome-c-oxidase, unless electron donation to cytochrome c becomes rate limiting.

Protein export from the mitochondrial matrix

Assembly of a functional mitochondrion requires import of proteins from the cytosol and export of proteins from the matrix. Most previous studies have focused on the import pathway followed by nucleus-encoded proteins. However, it is now clear that proteins encoded in the nucleus as well as those encoded in the mitochondrion also move from the matrix into and across the inner membrane, a process defined here as export. These exported proteins are found in at least three cellular locations: the inner mitochondrial membrane, the intermembrane space and the cell surface. Here, we consider the pathways for export and the relationships between import and export.

pH changes associated with cytochrome c oxidase reaction with H2O2. Protonation state of the peroxy and oxoferryl intermediates

pH changes associated with the mitochondrial cytochrome oxidase reaction with H2O2 have been studied. In the presence of ferricyanide or Tris-phenanthroline complex of CoIII as electron acceptors, reaction of H2O2 with the oxidized cytochrome oxidase is accompanied by a steady proton release with a rate constant of ca. 3 M-1.s-1 at pH 6.8. The acidification is completely inhibited by superoxide dismutase and its pre-steady-state kinetics correlates with that of the oxoferryl compound (F) accumulation. Apparently, the proton release is linked to superoxide generation by cytochrome oxidase under these conditions. In the presence of superoxide dismutase and without the electron acceptors, the H2O2-induced transitions of cytochrome oxidase from the oxidized to the peroxy (P) and from the peroxy to the oxoferryl state are not associated with any significant proton release or uptake. The results point to the following mechanism of O2- generation and protonation states of the cytochrome oxidase compounds P and F: [formula: see text]

A comparative EPR investigation of the multicopper proteins nitrous-oxide reductase and cytochrome c oxidase

The multicopper proteins, nitrous-oxide reductase (N2OR) and cytochrome c oxidase (COX), were investigated by EPR spectroscopy at microwave frequencies 2.4-35 GHz. Our results support a Cu-Cu interaction in COX and N2OR. At least 10 lines in the 2.7-GHz, 12 lines in the 4.6-GHz and 14 lines in the 9.2 GHz spectra were resolved for N2OR. Eight copper lines at 2.7 GHz, about nine lines at 4.6 GHz and about six lines at 9.2 GHz were resolved for COX. Simulations of the EPR spectra were consistent with most of the resonances of the multiline spectra, including regions in the center of the spectra where overlap of the three seven-line patterns is proposed. These simulations indicated that Cu-Cu interaction, in a mixed-valence [Cu(1.5) ... Cu(1.5)], S = 1/2 site is consistent with, if not proof of, the unusual spectral features observed for N2OR and COX.

Monitoring of iron(III) removal from biological sources using a fluorescent siderophore

We present here the physicochemical and biochemical properties of NBD-DFO, the 7-nitrobenz-2-oxa-1,3-diazole (NBD) derivative of the siderophore, desferrioxamine B (DFO) (Lytton et al., Mol. Pharmacol. 40, 584, 1991). Modification of DFO at its terminal amine renders it more lipophilic, imparts to it fluorescent properties, and is conservative of the high-affinity iron(III) binding capacity. NBD-DFO partitions readily from aqueous solution into n-octanol (Pcoeff = 5) and displays solvent-induced shifts in absorption and fluorescence spectra. The relative quantum yield of the probe's fluorescence increases over a 10-fold range with decreasing dielectric constant of the solvent. Fluorescence is quenched upon binding of iron(III) to the probe. We demonstrate here the application of NBD-DFO for the specific detection and monitoring of iron (III) in solutions and iron(III) mobilization from cells. Interactions between fluorescent siderophore and the ferriproteins ferritin and transferrin were monitored under physiological conditions. Iron removal from ferritin was evident by the demonstrable quenching of NBD-DFO fluorescence by scavenged iron(III). Quantitation of iron sequestered from cells by NBD-DFO or from other siderophore-iron(III) complexes was accomplished by dissociation of NBD-DFO-Fe complex by acidification and addition of excess ethylenediamin-etetraacetic acid. The sensitivity of the method and the iron specificity indicate its potential for monitoring chelatable iron under conditions of iron-mediated cell damage, iron overload, and diseases of iron imbalance such as malaria.

Derived amino acid sequences of the nosZ gene (respiratory N2O reductase) from Alcaligenes eutrophus, Pseudomonas aeruginosa and Pseudomonas stutzeri reveal potential copper-binding residues. Implications for the CuA site of N2O reductase and cytochrome-c oxidase

The nosZ genes encoding the multicopper enzyme nitrous oxide reductase of Alcaligenes eutrophus H16 and the type strain of Pseudomonas aeruginosa were cloned and sequenced for structural comparison of their gene products with the homologous product of the nosZ gene from Pseudomonas stutzeri [Viebrock, A. & Zumft, W. G. (1988) J. Bacteriol. 170, 4658-4668] and the subunit II of cytochrome-c oxidase (COII). Both types of enzymes possess the CuA binding site. The nosZ genes were identified in cosmid libraries by hybridization with an internal 1.22-kb PstI fragment (NS220) of nosZ from P. stutzeri. The derived amino acid sequences indicate unprocessed gene products of 70084 Da (A. eutrophus) and 70695 Da (P. aeruginosa). The N-terminal sequences of the NosZ proteins have the characteristics of signal peptides for transport. A homologous domain, extending over at least 50 residues, is shared among the three derived NosZ sequences and the CuA binding region of 32 COII sequences. Only three out of nine cysteine residues of the NosZ protein (P. stutzeri) are invariant. Cys618 and Cys622 are assigned to a binuclear center, A, which is thought to represent the CuA site of NosZ and is located close to the C terminus. Two conserved histidines, one methionine, one aspartate, one valine and two aromatic residues are also part of the CuA consensus sequence, which is the domain homologous between the two enzymes. The CuA consensus sequence, however, lacks four strictly conserved residues present in all COII sequences. Cys165 is likely to be a ligand of a second binuclear center, Z, for which we assume mainly histidine coordination. Of 23 histidine residues in NosZ (P. stutzeri), 14 are invariant, 7 of which are in regions with a degree of conservation well above the 50% positional identity between the Alcaligenes and Pseudomonas sequences. Conserved tryptophan residues are located close to several potential copper ligands. Trp615 may contribute to the observed quenching of fluorescence when the CuA site is occupied.

The NADH:ubiquinone oxidoreductase (complex I) of respiratory chains

The inner membranes of mitochondria contain three multi-subunit enzyme complexes that act successively to transfer electrons from NADH to oxygen, which is reduced to water (Fig. I). The first enzyme in the electron transfer chain, NADH:ubiquinone oxidoreductase (or complex I), is the subject of this review. It removes electrons from NADH and passes them via a series of enzyme-bound redox centres (FMN and Fe-S clusters) to the electron acceptor ubiquinone. For each pair of electrons transferred from NADH to ubiquinone it is usually considered that four protons are removed from the matrix (see section 4.1 for further discussion of this point).